de Lera Acedo heads the Cavendish Radio Astronomy and Cosmology group and is PI of the REACH experiment, a global 21-cm signal radiometer deployed in the Karoo desert, South Africa, targeting detection of the redshifted hydrogen signal from the Cosmic Dawn (zβ7.5β28). He has a PDRA opening for 21-cm cosmology data analysis. Research spans novel antenna design, ultra-low-noise receiver calibration (achieving ~80 mK RMSE), Bayesian foreground modelling, and RFI mitigation. He also leads the CosmoCube space mission concept for lunar-orbit 21-cm observations and is active in SKA development and HERA. He is actively hiring postdocs (PDRA posting live in 2025).
Simone De Liberato's Quantum Theory and Technology group explores quantum electrodynamics in semiconductor systems. Research: (1) ultrastrong and deep-strong light-matter coupling in polariton and circuit QED systems; (2) mid-infrared polariton physics with potential sensing applications; (3) virtual photon condensation and vacuum fluctuations in quantum materials; (4) positronium density measurements using polaritonic effects. Relevant to quantum sensing via strong coupling platforms.
De Nijs leads the Physics for Sustainable Chemistry group, studying light-matter interactions at molecular length-scales using plasmonic nanocavities, with applications spanning single-molecule SERS sensing, in-situ electrochemical monitoring, and plasmon-driven photocatalysis for green chemistry (e.g. plastics degradation).
De Sterke is a theorist-experimentalist of nonlinear and structured photonics. The group's signature recent contribution is the pure-quartic soliton: by engineering the dispersion of a waveguide so that the group velocity depends on the third power of frequency, they produce solitons with a different energy-width scaling from conventional ones, with direct consequences for mode-locked laser and frequency-comb design. The group also works on topological and non-Hermitian photonics and on THz metamaterials. Positioned against the established body of NV-ensemble quantum sensing work β DEER, nanoscale NMR and T1 relaxometry protocols operating at pT/sqrt(Hz) field sensitivity β the relevance is to the light side of the search rather than the spin side: dispersion-engineered comb and soliton sources are the local oscillators and reference clocks that any optical readout of a pT/sqrt(Hz) sensor ultimately depends on. Borderline inclusion; kept for the fundamental-light-physics criterion.
Defienne leads the Quantum Imaging Paris group at INSP, using spatial correlations and Hong-Ou-Mandel-type interference between entangled photon pairs to build microscopes that see through scattering media and correct optical aberrations without a spatial light modulator. His ERC-funded CORAMI project develops correlation-based adaptive optics as a universal add-on module for existing microscopes, targeting deeper (>1 mm), higher-contrast in-vivo imaging for neuroscientists, dermatologists, and ophthalmologists.
Degen leads the Spin Physics and Imaging group, one of the world's leading NV-center magnetometry labs. Research directions (as of 2025): (1) Scanning NV magnetometry of quantum materials β NV-tipped cantilevers image current flow (β²50 nm resolution) in graphene heterostructures and resolve domain walls in antiferromagnets/ferroelectrics; cryogenic scanning down to 350 mK in dilution refrigerator (published Appl. Phys. Lett. 2022). (2) Single-molecule NMR β shallow NV centers detect nuclear spins from surface-adsorbed molecules with sub-nanometer 3D resolution; 2022 Nano Lett. on amine-functionalized diamond surfaces; exploring chirality-induced spin selectivity at few-molecule level. (3) NV magnetometry protocols β reconstruction-free waveform sensing (1.1 ns time resolution, Nature 2025), gradiometric detection, spectrum demodulation for rapid scanning, multi-NV addressing. (4) Diamond nanoengineering β multicone pillar waveguides, surface engineering, scanning probe fabrication. ERC Proof-of-Concept 2025 for photonic IC single-photon NV excitation/detection for commercial quantum sensing.
Deisseroth co-invented optogenetics (light-gated ion channels for millisecond-scale neural control) and CLARITY-type hydrogel tissue-clearing methods that render intact brains optically transparent for whole-organ, cellular-resolution light-sheet and confocal imaging, together forming a foundational toolkit for causal, high-resolution circuit neuroscience.
Cees Dekker (Distinguished University Professor, BioNanoscience/Kavli) pioneered solid-state nanopores and single-molecule biophysics. Research: (1) solid-state nanopores for protein sensing and sequencing β detecting individual protein molecules by current blockade; (2) DNA loop extrusion by condensin and cohesin at the single-molecule level; (3) chromatin structure and chromosome organisation with bacteria-on-chip; (4) synthetic cell construction from the bottom up; (5) diagnostic nanopores for neglected diseases. NanoFront 51Mβ¬ NWO program leader; 2019 Nature paper on real-time DNA loop extrusion imaging.
Nynke Dekker (Full Professor, BioNanoscience) leads single-molecule biophysics of DNA replication and topology. Research: (1) single-molecule force-fluorescence microscopy β integrated optical tweezers and fluorescence for real-time imaging of replication machinery; (2) DNA topology β supercoiling, gyrase, topoisomerase dynamics with magnetic tweezers; (3) DNA/RNA-processing molecular motors. EMBO member; KNAW member. 2024 integrated force-fluorescence toolbox published.
Deleglise works on cavity optomechanics and microwave-to-optical photon transduction, aiming to coherently interconnect superconducting-circuit and optical-photon quantum-network nodes; he is also affiliated with LPENS' Quantic team on circuit-QED and bosonic-code quantum error correction.